WO2005073748A1

WO2005073748A1 - Imaging method based on fractal surface-filling or space-filling curves

Info

Publication number: WO2005073748A1
Application number: PCT/EP2004/053572
Authority: WO
Inventors: Richard Patzak; Daniel Gembris; Stephan Appelt; Friedrich Wolfgang HÄSING; Horst Halling
Original assignee: Forschungszentrum Jülich GmbH
Priority date: 2004-01-30
Filing date: 2004-12-17
Publication date: 2005-08-11
Also published as: DE102004005005B4; US20080231268A1; US7557574B2; EP1716429A1; DE102004005005A1; JP2007519452A

Abstract

The invention concerns an imaging method for use in nuclear magnetic resonance during which a constant static magnetic field acts upon a sample. An additional field is superimposed upon this static magnetic field. This additional field has, in at least one grating surface inside the sample volume, different field strength values at each point of the grating surface. The sample is excited by a high-frequency, electromagnetic alternating field, and the electromagnetic radiation radiated from the excited sample is extracted and evaluated for generating images. The invention also concerns an NMR imaging method during which the signal is extracted along a fractal, space-filling trajectory described by a Hilbert curve.

Description

Imaging method based on self-similar area or space-filling curves

Description; The present invention relates to an imaging method and an associated device for nuclear magnetic resonance, which are based on self-similar area-filling or space-filling curves. Magnetic resonance or spin resonance is based on the fact that atomic nuclei (in particular atomic nuclei in molecules) are excited by radio waves and in turn emit radio waves. The nuclear magnetic resonance effect can also be exploited and in particular in the imaging of the following nuclei:, ³ C, ¹⁵ N, ^{1 29} Xe, ³ He, ²³ Na and ^{, 7} 0, the reason for this is the self-rotation - the spin - of the protons. As a moving electrical charge, this spin generates a small, atomic magnetic field that interacts with the magnetic moments of the neighboring protons. Depending on the environment, a characteristic magnetic moment of the entire molecule is created.

MR measurements on the human body are ideal

Hydrogen cores because they are by far the most common. If the person to be examined is exposed to a strong static magnetic field, the spins orient themselves of protons in the body after this external magnetic field. In general, a high-frequency electromagnetic field is applied perpendicular to the static magnetic field. At a certain frequency, the Larmor frequency, the spins are deflected, they resonate.

If this excitation pulse is now switched off, the spins of the protons "fold back" in their original direction - and lose energy which they emit as radio waves. The magnetic part of this radiation can be measured by a receiver coil and finally evaluated on the computer.

The spins of the protons are excited layer by layer by switching on an additional gradient magnetic field (layer selection gradient) in a precisely defined time. The returned radio waves can be precisely localized when using the reading and phase gradient; pixels are created which can be combined to form a two-dimensional image. Magnetic resonance thus represents a widely used, non-invasive method for examining the human body. Functional magnetic resonance tomography is used, for example, to display local brain activity,

A fast image acquisition is possible with the so-called ec / io planar imaging (EPI), which is a fast measurement technique in which the entire k-space (2D) can be recorded with a single excitation pulse. The EPI reads out the Gradient echoes recorded in k-space lines.

EPI is by far the fastest method in MR imaging. The classic EPI sequence uses a single excitation and then collects all data using gradient echo technology. An MR image can be created in less than 1 00 ms.

There are spin echo and gradient echo variants of the EPI sequence. The gradient echo variant (V-sensitive) is used for measuring brain activity. The functional MR imaging is based on the BOLD effect: Blood Oxygen Level Dependent Effect. The spin echo variant (T ₂ sensitive) uses a 1 80 ° RF pulse after the excitation pulse in order to minimize the field inhomogeneities. Using an additional 1 80 ° pulse, T, weighted images can also be recorded with the EPI. The pure gradient echo variant is particularly suitable for cardiac imaging. With EPI, the frequency encoding gradient oscillates (continuously or with plateau intervals), creating a series of gradient echoes.

In contrast to conventional MR imaging techniques, the phase encoding gradient is switched during reading. This means that all echoes are given a different phase encoding: the raw data matrix is filled line by line with an alternating direction.

In gradient echo, the echo signal is generated by switching a pair of dephasing and rephasing gradients. For this purpose, the frequency coding gradient is switched on directly after the excitation pulse with negative polarity. It first causes the spins to fan out. Then you switch it to positive polarity. Now the spins are brought back into phase (rephasing) and there is an echo.

When using shorter repetition times, a tilt angle less than 90 ° provides a better signal-to-noise ratio than a 90 ° Pulse. To illustrate this, only one (the first) excitation pulse is considered. For example, an excitation pulse with a tilt angle of 20 ° produces a sufficient transverse magnetization of 34% of the maximum value. The longitudinal magnetization is 94% of the maximum value. A high longitudinal magnetization is again available at the next excitation pulse. In the case of short repetition times (T _R small compared to T.), a stronger MR signal is therefore generated with a smaller tilt angle than with a 90 ° pulse.

The longitudinal magnetization recovers faster the smaller it is. After each deflection by the tilt angle, the remaining longitudinal magnetization is initially smaller than before. It then recovers faster the smaller it is. After several excitation pulses, a balance is struck between these two opposing tendencies. The longitudinal magnetization and thus also the signal is then the same after each pulse. This state of equilibrium is also called steady state,

The variation of the tilt angle changes not only the signal-to-noise ratio, but also the contrast behavior of the MR image. With the so-called Ernst angle, a maximum signal results for a certain repetition time T _R and the T- time dependent on the tissue. For diagnostic purposes, however, a tilt angle is chosen in which the contrast is not necessarily optimized, but rather the signal-to-noise ratio.

Images weighted for T. generate a larger tilt angle than that

Ernst-Winkel a better T. contrast, at For proton density weighting, a smaller tilt angle is desirable.

Since the gradient echo sequence is very fast and can have very short repetition times T _R compared to the T ₂ time (down to 8 ms for the fastest sequences), there is still a residual transverse magnetization from the previous excitation. There are two ways to deal with this fact: The transverse magnetization is destroyed or used.

In the so-called FLASH method (Fast Low Angle Shot), the remaining transverse magnetization is destroyed by a spoiler gradient before the repeated excitation pulse with the aid of the FLASH sequence. the steady state of longitudinal magnetization sets in after a few excitation pulses. Only this is used for imaging. A disadvantage of the methods described above, particularly in the case of echo planar imaging, is the high sound development associated therewith. This is based on the effect of the Lorentz force on the gradient coils in the magnetic field, which are flowed through by a current of a few amperes that varies over time (with frequencies around 500 Hz). With increasing magnetic field strength, the sound intensity of the gradient switching processes increases. These are often noticeable in the form of loud knocking noises, in some devices also as tonal noises. As a result, it is disadvantageously necessary to limit the noise pollution as a function of the task to be performed by the test subject.

In the case of auditory experiments, restrictions arise from the fact that the image recording noise can partially mask the stimuli. Furthermore, this noise generates as an additional acoustic stimulus a difficult to control activation of auditory areas, the effects of image noise on the auditory cortex are the subject of intensive research. In addition, disadvantageous process-related "ghosting" artifacts are produced in the Ec o-Planar imaging with line-by-line readout. "Ghosting" artifacts are created by overlaying the actual image with an image offset in the phase coding direction. An application of Hubert curves in the field of MR imaging is also known from the prior art and was described in: "Detecting Discriminative Functional MRI Activation Patterns Using Space Flowing Curves", D.Kontos, V.Megalooikonomou, N.Ghubade, C Faloutsos, EMBC2003, pp.963-966. In this case, an evaluation of already (conventionally) recorded MR data is carried out with regard to patterns that are characteristic of a clinical picture. The Hilbert curve maps 3D data sets to 1-D data structures, which are then compared with each other.

Against the background of the disadvantages described above, it is therefore an object of the present invention to provide a method and a device which enable a comparatively quieter execution and improve the imaging, as well as less stress on the device and reduce the demands on it.

This object is achieved by the generic method with the features of claims 1 and 7 and by a Vorrich. solved according to claim 1 3. Advantageous designs result from the subclaims

The imaging method for nuclear magnetic resonance according to the invention provides that a constant magnetic magnetic field acts on a sample. Typically, the s.ai iscne magnetic field has a strength between e ^x ao, 25 and 10 T in current MR tomographs. The basic field is necessary in order to ensure a minimum size of the signal-to-smoke behavior. When using hyperpolarized cores, the basic field can be comparatively very small. all, ciso have less than 0.25 T,

The Konslan + e sta. The magnetic field is superimposed by an additional field. The additional field has the property of having a different, only e'nrna, field strength value for each point of at least one grid area within the sample volume in each point of the Gilter plane.This can be several Giiter areas and these do not have to be must be pianar it can be spherical or cylindrical surfaces uie sample is also excited by a high-frequency, alternating electromagnetic field. The imaging method according to the invention further provides that the electromagnetic radiation emitted by the excited sample is recorded and evaluated for image generation by using the so given additional field, a time-varying gradient field can be omitted. It follows that a magnetic resonance (MR) image with a single one

To record high-frequency excitation with time-varying gradients, which in turn advantageously prevents the sound development associated therewith. The field can be kept constant in time over several measurements, which makes broadband high-frequency excitation necessary. Or it can be switched on for each measurement using a comparatively narrow band excitation. With narrow-band excitation, the resonance frequencies of the spins are close to one another, which is achieved, for example, by switching off the additional field. With a broadband excitation, the additional field can remain, which is technically easier to implement. In the method according to the invention, the electromagnetic radiation emitted by the excited sample is also read out and evaluated for image generation.

According to a further embodiment of the method according to the invention, the additional field is described by area-filling or space-filling curves, these curves having a unambiguous assignment of the field strength value and point of the grid. Due to the unambiguous assignment between location and frequency, the image can be reconstructed using a 1-D Fourier transformation. For example, a raw data matrix is filled with data and converted into an MR image by means of a 1-D Fourier transformation done sequentially. For example, the examination object is transported past the measurement arrangement or through it, or individual segments of the measurement arrangement are activated in succession. The additional field is described by area-filling or space-filling curves. For example, these are curves that are constructed using L systems, as described in "Chaos and Fractals", Peltgen et al. This advantageously reduces field jumps between adjacent points, which in turn minimizes artifacts. The reason for this is that the for the most optimal fulfillment of the uniqueness condition required jumps in the field strength can only be approximately achieved (constant transition of the field strength between neighboring grid points, technical effort for field generation). A violation of the uniqueness condition lies e.g. B. before when two different locations are mapped to a frequency in the spectrum. It can no longer be determined from which location a signal originates. If necessary, the signal can then be divided equally between the two locations. This leads to smearing of the image, especially along lines that lie between areas with very different field strengths. The magnetic field defined in this way is generated, for example, with a current-carrying coil arrangement, which is determined by numerical optimization. This is a magnetostatic calculation, whereby the differences between the specified magnetic field values and the numerically determined values are to be minimized.

A further embodiment of the method according to the invention provides that several areas of the sample are measured simultaneously, that is to say in parallel in time. For example, this is achieved by using a measuring arrangement that is designed in a correspondingly multiple manner. As a result, the method according to the invention can be carried out particularly quickly.

In a further advantageous variant of the invention, echoes are generated. This is a fast measurement technique, which is, for example, spin echo and gradient echoes. To generate the echo, it is provided in a further embodiment that the additional field changes its sign via the tent. By changing the sign, gradient echoes can be generated analogously to the known MR imaging, but not for individual k-space lines, but for an entire image at a time.This allows fast spectroscopic MR imaging to be carried out: excitation and recording of several successive ones echo images. In a further embodiment of the method according to the invention, the additional field is described by a Hilbert curve, a special space-filling and area-filling curve. If the Hilbert curve is used, a hierarchical artifact structure results, ie there is a negative correlation between the artifact size and frequency. This advantageously achieves a compromise, since weak artifacts can be tolerated more than strong ones.

The method according to the invention can be used to measure current distributions or magnetic fields. Because no gradients are switched, no (unwanted) currents can be induced in the sample.

Another alternative imaging method for nuclear magnetic resonance provides that spatially detectable transverse magnetization is generated in the sample by means of high-frequency excitation. By switching imaging gradients, for example, a spatially resolved measurement of the transverse magnetization takes place. The signal is read along in a data acquisition phase self-similar, space-filling curves and a raw data matrix is formed from the data obtained. With the aid of a Fourier transformation, an image is obtained from the raw data matrix. In known methods, the raw data matrix (so-called k-space) is generated line by line or by scanning on circular paths. In conventional cellular EPI scanning, the reading gradient (often operated with almost maximum amplitude) alternates between each k-space line, which creates the sequence-typical noises with frequencies in the order of 500 Hz. "Sequence" denotes the sequence of high-frequency excitations, gradient pulses and data acquisitions. In the method according to the invention, the sign of the gradients changes significantly more often, with almost every k-space point; which practically corresponds to a sequence of EPI 'blips' Blip 'is a gradient pulse that is required to switch from one k-space line to the next, which means that the gradient noise is advantageously shifted to a higher frequency range (with a resolution of 64x64 from frequencies around 500Hz) Frequencies around 32000 Hz) This effect can be used to advantage for the execution of auditory brain imaging studies, as these are partially impaired by gradient noises, partly because human hearing is particularly sensitive in the frequency range relevant for speech production.

Elaborate and expensive measures to reduce sound developments through passive or even active

Sound attenuation can advantageously be eliminated by the method according to the invention. According to the prior art, sequence-technical measures for sound reduction exist in the Extension of the k-space re-addition and the reduction of the k-space lines, which disadvantageously increases the measurement time or reduces the resolution of the measurement. The method according to the invention also avoids longer-lasting gradient plateaus ¹ , which relieves the load on the gradient amplifiers or less technical requirements on the gradient amplifiers. Another advantage of the image coding according to the invention is a reduction in the periodicity of the gradient time profile, which in turn reduces mechanical resonances of the imaging device.

According to a further embodiment of the method according to the invention, the space-filling trajectory is described by a Hilbert curve. In the Hilbert curve (trajectory), neighboring k-space points are scanned at similar points in time, as a result of which artifacts are distributed more evenly over the k-space. An analogous procedure exists for methods for color space reduction in spatial space images (“dither algorithms ").

A further embodiment provides that the data acquisition takes place in segments, i.e. The k-space is divided into individual segments, which in turn are scanned along a space-filling curve (“hybrid method”), i.e. an excitation pulse is generated for each segment. Segmentation can be particularly advantageous if the relaxation times are short,

The aforementioned methods can advantageously be implemented using known and existing devices for magnetic resonance imaging, for example their pulse sequence can only be adapted. A further embodiment of the method according to the invention provides that the image coding takes place in 3 dimensions. It is therefore suitable for so-called echo volum imaging. This is a three-dimensional EPI, with the layer selection advantageously being dispensed with.

Another embodiment provides that parts of the measuring arrangement are moved past the sample or through the sample or individual gradient coils are activated one after the other.

The invention further relates to devices for carrying out the methods described above in each case with the associated advantages. According to a first device, a constant, static magnetic field is provided which acts on a sample. The device comprises means for generating an additional field which is superimposed on the static magnetic field and which has different field strength values in at least one grid area within the sample volume at every point of the grid area. Furthermore, means are provided for generating a high-frequency, alternating electromagnetic field, which excites the sample. In a particularly simple variant, the means for generating a high-frequency alternating electromagnetic field comprise an RF transmission / reception coil that encloses the entire sample. The means for reading out serve to register the electromagnetic radiation emitted by the excited sample. Furthermore, means are provided for evaluation and image generation. For example, the devices are known MR imaging devices. By using the so predetermined time field, a time-varying gradient field can be omitted. It is consequently possible to record a magnetic resonance (MR) image with a single high-frequency excitation without time-varying gradients, which in turn advantageously prevents the associated sound development,

According to a further embodiment of the device according to the invention, the means for generating an additional field comprise a micro-coil arrangement. For example, they are so-called micro-coil arrays, as are used in surface measurement or in biology or biochemistry for screening systems. The field can be generated, for example, with micro-coils that are arranged in a matrix-like (nxn) manner on a rectangular surface. The sample rests, for example, on these coils or adjoins them directly. In order to be able to describe the additional field, for example by means of a Hilbert curve, a special space and area-filling curve, the current strengths of the microcoils are defined by the values along this Hilbert curve with a linear increase in the field strength along the curve. Another device according to the invention provides that means are provided for generating a detectable transverse magnetization in a sample. The device also provides means for data acquisition of a signal along a self-similar, space-filling trajectory. Furthermore, means for data evaluation are provided which form a raw data matrix from the acquired data and which obtain an image from the raw data matrix using Fourier transformation. The device according to the invention advantageously provides for a reduction or frequency shift of the “sequence” noise. The effect can be advantageous for performing auditory Brain imaging studies can be used because they are sometimes severely affected by gradient noise. This is partly due to the fact that human hearing is particularly sensitive in the frequency range relevant to speech generation. Elaborate and expensive measures for reducing sound developments through passive or even active sound attenuation can advantageously be omitted in the device according to the invention. The device can be kept comparatively simple, since longer-lasting 'gradient plateaus' are avoided, which results in a relief of the gradient amplifiers or lower technical requirements for the gradient amplifiers. A further advantage of the image coding according to the invention is a reduction in the periodicity of the gradient time curve, which in turn reduces mechanical resonances of the imaging device.

About the flauren: Figure 1 is a 3D representation of a two-dimensional Hilbert curve. The z coordinate indicates the point in time at which the corresponding k-space point is reached or the strength of the additional field as a function of the location.

Figure 2a shows an example of the k _χ component of a Hilbert trajectory for a resolution of 64x64 voxels.

Figure 2b shows an example of the k component of a Hilbert trajectory for a resolution of 64x64 voxels. FIG. 3a shows the x component of the gradient field for the coding of the Hilbert trajectory, which results from the k (t) curve by time derivation. FIG. 3b shows the y component of the gradient field for the coding of the Hilbert trajectory, which results from the k (t) curve by time derivation.

Summary: The present invention relates to an imaging method and apparatus for nuclear magnetic resonance. On the one hand, the method provides for image coding by means of an additional field, which has a different field strength value that occurs only once for each point of a 2-dimensional grid area within the sample. B. is the case with fields based on self-similar, area- or space-filling curves, on the other hand, a reading of the resonance behavior of a sample can be provided along a space-filling or area-filling curve, in the first variant, a magnetic resonance (MR) image can be provided a single high-frequency excitation without time-varying gradients, which advantageously prevents the associated Schailenfwickiung, in the second variant, the noises generated during the reading are advantageously shifted to another frequency range in which the human ear has a lower sensitivity, moreover, so the device is relieved and the technical requirements placed on it are reduced. Furthermore, it can be carried out with known and existing devices.

Claims

Expectations:

1 . Imaging method for nuclear magnetic resonance, whereby a constant, static magnetic field acts on a sample, whereby an additional field is superimposed on the static magnetic field, which has different field strength values in at least one grating area within the sample volume at every point of the grating area, the sample being transmitted by a high-frequency, electromagnetic Alternating field is excited, and the electromagnetic radiation emitted by the excited sample is read out and evaluated for image generation,

2. imaging method for nuclear magnetic resonance according to the preceding claim, wherein a 1 D Fourier transform is used,

3. Imaging method for nuclear magnetic resonance according to one of the preceding claims, wherein the additional field is described by area or space-filling curves, for these curves there is a unique assignment between field strength values and point of the grating.

4. The imaging method for nuclear magnetic resonance according to one of the preceding claims, wherein several areas of the sample are measured simultaneously.

5. Imaging method for nuclear magnetic resonance according to one of the preceding claims, wherein echoes are generated.

6. imaging method for nuclear magnetic resonance according to the preceding claim, wherein the additional field changes its sign over time to generate the echo.

7. imaging method for nuclear magnetic resonance according to one of the preceding claims, wherein the additional field is described by a Hilbert curve. 8. Imaging method for nuclear magnetic resonance, whereby a spatially detectable transverse magnetization is generated in a sample, in the data acquisition phase the signal is read out along a self-similar, space-filling trajectory and a raw data matrix is formed and an image is obtained from the raw data matrix with Fourier transformation.

9. imaging method for nuclear magnetic resonance according to the preceding claim, wherein the self-similar, space-filling trajectory is described by a Hilbert curve.

1. Imaging method for nuclear magnetic resonance according to one of the preceding claims 8 or 9, wherein the data acquisition takes place in segments, 1. Imaging method for nuclear magnetic resonance according to one of the preceding claims, wherein an image coding is carried out in 3 dimensions,

2. Imaging method for nuclear magnetic resonance according to one of the preceding claims, wherein parts of a Measurement arrangement past the sample or moved through the sample or segments of the magnetic field or magnetic fields are activated one after the other.

1 3. Device for performing the method according to one of claims 1 to 7, with a constant, static magnetic field, which acts on a sample, with means for generating an additional field, which is superimposed on the static magnetic field and in at least one grid area within the Sample volume in each point of the grid area has different field strength values, with means for generating a high-frequency, alternating electromagnetic field, which excites the sample, with means for reading out the electromagnetic radiation emitted by the excited sample and with means for evaluation and image generation,

4. The device according to claim 1 3, wherein the means for generating an additional field comprise a micro-coil arrangement .5. Device for carrying out the method according to one of claims 8 to 1 2, with means for generating a spatially detectable transverse magnetization in a sample, with means for data acquisition of a signal along a self-similar, space-filling trajectory, with means for data evaluation, the one from the acquired data Form raw data matrix and obtain an image from the raw data matrix with Fourier transformation.